Method and device for generating short pulses

ABSTRACT

There is described a method and corresponding pulse generating device, for generating an output pulse signal having an output pulse duration. The method comprises: receiving at an input port an input pulse signal comprising an input pulse duration; duplicating the input pulse signal into a first digital pulse signal and a second digital pulse signal each comprising the input pulse duration; delaying at least one of the first and the second digital pulse signals by a time delay to obtain respectively a first and a second delayed digital pulse signal, a time delay difference between the first and the second delayed digital pulse signals being substantially equal to the output pulse duration; logically combining the first and the second delayed digital pulse signals to generate the output pulse signal with the output pulse duration smaller than the input pulse duration; and outputting the output pulse signal at an output port.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is filed under 37 CFR 1.53(b) as a continuationapplication of U.S. patent application Ser. No. 13/058,922 filed Feb.14, 2011. This application claims priority under 35USC§120 or 365(c) ofU.S. patent application Ser. No. 13/058,922 filed Feb. 14, 2011 and PCTApplication PCT/CA2009/001139, filed Aug. 13, 2009, and entitled “METHODAND DEVICE FOR GENERATING SHORT PULSES”, which claims priority under35USC§119e of U.S. provisional patent application 61/136,111 filed Aug.13, 2008, and entitled “METHOD AND DEVICE FOR GENERATING PULSES”, thespecification of which is hereby incorporated by reference.

TECHNICAL FIELD

The present specification relates to electronics, and more particularlyto methods and devices for generating short pulses.

BACKGROUND

Many applications require that relatively short pulses be generated.There are many types of existing electronic devices for generating suchshort pulses. However, they are typically limited to the generation ofpulses each having a pulse duration of one nanosecond or more. There ishowever a need to generate pulses having instead a pulse duration in theorder of a few picoseconds, or a few tens of picoseconds. Prior artdevices are typically not suitable for addressing such a need.

Typical pulse generation methods used in prior art devices involve, forexample, differentiating a relatively high slew rate electrical signal,or combining an input analog signal to its inverse delayed by arelatively small delay typically chosen to be in the order of magnitudeof the desired pulse duration. While these two methods of generatingpulses are relatively efficient for the generation of relatively longpulses, they are typically not usable to produce very short pulses. Forexample, for the duration of a pulse generated using the prior artdifferentiation method to be in the desired range, the signal would needto increase at a rate that is not typically achievable at relatively lowcosts.

U.S. Pat. No. 6,433,720 issued on Aug. 13, 2002 to Libove illustratesanother manner of generating pulses which basically provides for thegeneration of pulses having variable, adjustable or tunable, pulsedurations. This is done by triggering the pulse generation at differentcontrol voltage levels of a relatively low slew rate voltage signal.Such prior art generators are however typically very sensitive to noisesince any noise present in the relatively low slew rate voltage signalor in the control voltage may change the exact start and finish timings,which affect its duration.

There is thus a need for improved devices and method for generatingpulses with relatively short pulse durations.

SUMMARY

In accordance with an embodiment, there is provided a pulse generatingdevice for generating an output pulse signal having an output pulseduration. The device comprises: a signal duplicator for receiving aninput pulse signal comprising an input pulse duration, the signalduplicator for duplicating the input pulse signal into a first digitalpulse signal and a second digital pulse signal each comprising the inputpulse duration; a delay component operatively coupled to the signalduplicator, the delay component for delaying at least one of the firstand the second digital pulse signals by a time delay to obtainrespectively a first and a second delayed digital pulse signal, a timedelay difference between the first and the second delayed digital pulsesignals being substantially equal to the output pulse duration; and alogic circuit coupled to the delay component, the logic circuit forcombining logically the first and the second delayed digital pulsesignals to generate the output pulse signal with the output pulseduration smaller than the input pulse duration, the logic circuit foroutputting the output pulse signal.

In accordance with an embodiment, there is provided a method forgenerating an output pulse signal having an output pulse duration. Themethod comprises: receiving at an input port of an electronic device aninput pulse signal comprising an input pulse duration; duplicating theinput pulse signal into a first digital pulse signal and a seconddigital pulse signal each comprising the input pulse duration; delayingat least one of the first and the second digital pulse signals by a timedelay to obtain respectively a first and a second delayed digital pulsesignal, a time delay difference between the first and the second delayeddigital pulse signals being substantially equal to the output pulseduration; logically combining the first and the second delayed digitalpulse signals to generate the output pulse signal with the output pulseduration smaller than the input pulse duration; and outputting theoutput pulse signal at an output port of the electronic device to drivean electronic or electrical circuit.

Other embodiments, advantages and features will become more apparentupon reading of the following non-restrictive detailed description,given by way of examples with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWING

In the appended drawings:

FIG. 1 is a schematic view of a pulse generating device in accordancewith an embodiment;

FIG. 2 is a schematic view of the pulse generating device of FIG. 1,with signal names, in accordance with an embodiment;

FIG. 3 is a graphical view of exemplary signal waveforms at variouspoints within the pulse generating device of FIG. 1, in accordance withvarious embodiments;

FIG. 4 is a flowchart which illustrates a method for generating a pulsein accordance with an embodiment; and

FIG. 5 is an example of an output pulse signal versus time as outputtedby the pulse generating device of FIG. 1, in accordance with anembodiment.

DETAILED DESCRIPTION

FIG. 1 illustrates a pulse generating device 10 in accordance with anembodiment and which may be used to drive an electronic circuit (notshown) such as an amplifier, an amplifier driver, a modulator, anelectro-optical circuit, a laser, a pulsed laser, a radar, a LIDAR, etc.The pulse generating device 10 generates an output pulse 44 having anoutput pulse duration Tp. The output pulse 44 is generated from an inputpulse 12 having an input pulse duration Ti longer than the output pulseduration Tp. In an embodiment, a complementary output pulse 46 is alsogenerated, the pulse 46 also having an output pulse duration Tp.

In some embodiments, the pulse generating device 10 includes an inputport 11 for receiving an input signal 12 having a form as shown in thefigure. In alternative embodiments, the pulse generating device 10includes a signal generator 13 for generating the first input signal 12.

The first input signal 12 defines a first signal attack portion 14, afirst input signal sustain portion 16 and a first input signal decayportion 18. The first input signal sustain portion extends between thefirst input signal attack and decay portions 14 and 18. Therefore, thefirst input signal 12 has the shape of a pulse. The first input signalattack, sustain and decay portions 14, 16 and 18 have relatively longdurations.

The pulse generating device 10 uses the first input signal 12 togenerate a pulse 44 having duration Tp that is typically made muchshorter than the duration Ti of the first input signal 12. Also, whilethe first input signal 12 as shown on FIG. 1 has a relatively flatsustain portion 16 and respectively linearly increasing and decreasingattack and decay portions 14 and 18, these signal portions 14, 16 and 18may take other shapes. In an embodiment, for example, the first inputsignal 12 is processed by the pulse generating device 10 in such amanner that only a relatively small portion of the first input signal 12is used to generate the output pulse 44 (and/or complementary outputpulse 46), allowing for various shapes to be taken by the attack,sustain and decay portions 16, 14 and 18.

As seen in the embodiment shown in FIG. 1, the signal generator 13generates a single-ended first input signal 12. This first input signal12 is optionally fed into a phase splitting device 20, which produces adifferential signal (i.e. complementary signals 21 and 22). The phasesplitting device 20 can be implemented as a variety of signal polarityinverting devices, for example, such as a balun transformer. The use ofa balun transformer produces a differential signal that is usable withdifferential logic components, which may represent an advantage in someapplications.

The phase splitting device 20 outputs the second signal 22 and theinverted second signal 21. Signal 21 is synchronized with the signal 22and has a substantially identical shape as signal 22, though inversed.Signal 22 has substantially the shape of the input pulse signal 12,although amplitude levels, or voltage values, which characterize any oneof signals 21 and 22 may not be the same as shown in FIG. 1 (nor thesame as the first input signal 12).

The complementary signals 21 and 22 are fed into a signal duplicator 23.The duplicator 23 duplicates each one of the signals 22 and 21 toproduce a respective duplicated pair of digital signals 28 and 30. Thepair of digital signals 28 and the pair of digital signals 30 arecomplementary to each other (i.e. inverted versions of one another).

Alternatively, when the optional phase splitting device 20 is not used,the input signal 12 is directly fed into the duplicator 23 to produceone pair of duplicated signals 28 (or 30). The pair of duplicatedsignals 28 (or 30) comprises a first and a second digital pulse signals.In another embodiment, the input signal 12 is used in a single endedinput configuration with a balanced output.

In FIG. 1, the signal duplicator 23 comprises a signal compressor whichcompresses the attack and decay portions 14 and 18 of the signals 21 and22 (or the input signal 12 when there is no phase splitting device 20)to output signals 28 and 30 having relatively short attack and decaytime durations. As also illustrated in FIG. 1, the duplicator 23 withcompressor can be implemented as a fan-out slope compressor such as acommercially available differential clock/data fan-out buffer. Thecompressor may also be implemented as a separate component, coupled tothe duplicator (not shown).

The compressor is optional since in some cases, the input signal 12 hasattack and decay portions 14 and 18 which are already suitable and donot require compression.

In some embodiments, compressing the second and inverted second signals22 and 21 is performed by using relatively large gain amplifiers thatsaturate at relatively low input voltages. In this case, as soon as thereceived signals 22 and 21 reach a relatively small level, the amplifiersaturates and produces a relatively flat output. Therefore, theamplifier gain dictates by what factor the slopes of the attack anddecay portions of the signals 22 and 21 are increased. A similar effectis produced in reverse on the decay portions of signals entering theamplifiers.

As detailed above, the duplicator 23 outputs a first digital pulsesignal 28 a and its duplicate, second digital pulse signal 28 b. Theduplicator also outputs a first inverted digital pulse signal 30 a andits duplicate, second inverted digital pulse signal 30 b.

The digital pulse signals 28 a, 28 b and 30 a, 30 b each have arespective signal attack portion 32, a signal sustain portion 34 and asignal decay portion 36. The signal sustain portion 34 extends betweenthe signal attack and decay portions 32 and 36. As seen in the drawings,the signal attack portion 32 increases much more rapidly than the signalattack portion 14 of the input signal 12 (or of signals 21 and 22), andthe signal decay portion 36 decreases much more rapidly than the signaldecay portion 18 of the input signal 12 (or of signals 21 and 22).

The digital pulse signals 28 a, 28 b and 30 a, 30 b are fed into a delaycomponent which is represented in FIG. 1 as a combination of two delaycomponents 38 and 40. These may however be combined within onecomponent, or alternatively only one delay may be used. Having two delaycomponents can allow compensating for delays present in other componentsof the pulse generating device 10 that would result in non timingissues.

In the illustrated embodiment, the first delay component 38 receives thefirst digital pulse signal 28 a and the first inverted digital pulsesignal 30 a. Similarly, the duplicate of the first digital pulse signal28 a, referred to as the second digital pulse signal 28 b, and theduplicate of the first inverted digital pulse signal 30 a, referred toas the second inverted digital pulse signal 30 b are fed into the seconddelay component 40.

The first and second delay components 38 and 40 produce respectively afirst delayed digital pulse signal 41 and a second delayed digital pulsesignal 43, each of these signals being a differential signal includingthe signal itself and its inverse, as illustrated in FIG. 1. Inembodiments not comprising the phase splitting device 20 or where thesignal duplicator 23 provides a single ended output, the first andsecond delay components 38 and 40 each respectively may outputnon-differential delayed digital pulse signals 41 and 43 (i.e. withouttheir respective inverse).

The first and second delay components 38 and 40 can be any suitabledelay device. For example, the first and second delay components mayinclude logic gates having response times that provide a delay in thetransmission of signals. Alternatively, the first and second delaycomponents 38 and 40 can be implemented as transmission lines printed ona printed circuit board. In yet other embodiments, the first and seconddelay components 38 and 40 may be implemented from commerciallyavailable delay chips providing a relatively precise delay as per theirspecifications and, in some cases, which also allow for the selection ofthe duration of a respective time delay provided by each of thecomponents 38 and 40. Such selection may be provided by way oftunability. For example, by adjusting a time delay difference betweenthe first and second delays of the first and second delay components 38and 40, the pulse duration Tp of the output pulse signal 44 can beadjusted.

The first and second delayed digital pulse signals 41 and 43, and/ortheir inverses, are fed into a logic circuit 42 which logically combinesthe first and second delayed signals 41 and 43 (and/or their inverses)such that there is a non-zero output at the valid output port locationof the logic circuit 42 only when both signals 41 and 43 comply withpredetermined values, such as defined in the truth table provided belowin Table 1. FIG. 2 provides a correspondence between the Input 1 and theInput 2 signal names as listed in Table 1 below and the numeralreferences provided in FIG. 1 and described herein.

Still in reference to both FIGS. 1 and 2, and the Table 1 below, thelogic circuit 42 comprises gates (not shown) which are meant toimplement a logic defined by such a truth table. A variety of logiccombinations may thus be implemented by the circuit 42, and the logiccircuit 42 may take on a variety of circuit implementations. The logiccircuit 42 can be any suitable logic combiner which, for example,includes logic components that are activated/deactivated by transitionsin input pulses, instead of being based on the voltage level of theirinputs.

To ensure the generation of good quality impulsions, the logic circuit42 is implemented to have a response time as fast as, or faster than,the pulse duration Tp. For example, the logic circuit 42 may include aXOR gate or an AND gate or its boolean equivalent, which provides anoutput pulse rate having respectively twice and once the input frequencyof the first input pulse.

TABLE 1 Output Logic wave see Valid Case Input 1 Input 2 function FIG. 3output 1 D3 \D4 AND OUT 1 44 1 ≡ 2 2 \D3 D4 NOR OUT 1 46 3 \D3 D4 ANDOUT 3 44 3 ≡ 4 4 D3 \D4 NOR OUT 3 46 5 D3 D4 XOR OUT 2 44 6 \D3 \D4 XOROUT 2 44 7 D3 \D4 XRN OUT 2 46 8 \D3 D4 XRN OUT 2 46

In some embodiments, one of the first and second delayed digital pulsesignals 41 and 43 is inverted, for example by crossing the two wires orsignal transmission lines on which this signal is propagated beforebeing input in the logic circuit 42.

FIG. 3 illustrates timing diagrams for the various signals describedhereinabove and listed in Table 1. Signals 22 and 21 correspondrespectively to signals D0 and \D0; signal 28 a and its duplicate 28 bcorrespond respectively to signals D1 and D2; signal 30 a and itsduplicate 30 b correspond respectively to signals \D1 and \D2; signals41 and 43 correspond respectively to signals D3 and D4; the inverses ofsignals 41 and 43 each respectively correspond to signals \D3 and \D4;signal 44 (or 46) correspond to any of the valid OUT1, OUT2 and OUT3 asprovided by the above Table 1.

FIG. 3 illustrates various OUT signals waveforms such as OUT1, OUT2 andOUT3, which would be outputted in time (t) as either output pulse signal44 or 46 depending on the logic function performed by the logic circuit42, with reference to Table 1 above.

As seen from the FIGS. 1 to 3, differential digital logic componentssuch as the duplicator 23 and the logic circuit 42 are used. Suchdifferential digital logic components accept the second and invertedsecond signals 22 and 21, transform them into a differential logicsignal formed by a first digital signal component and a second,complementary digital signal component which is simply the inverse ofthe first digital component. Both digital components each have either apredetermined voltage level or a zero voltage level (or a voltage levelassociated with either one of 0 and 1). Differential signals have theadvantage of being, at least within a predetermined operational range,relatively insensible to the absolute voltage above ground level aboutwhich they vary in time. Contrary to non-digital signals, such signalsrepresent logic values as a difference between the two voltagespropagating onto two different transmission wires or transmission lines.

The above described pulse generating device 10 can be manufactured usingexisting components at relatively low costs or as an integrated circuit,within a single chip. It may also be implemented to allow a matchingwith potential applications. It has also been shown that someimplementations allow robustness to temperature variations and noise.

Now referring to FIG. 4, there is described a method 100 for generatinga short pulse signal in accordance with an embodiment. The method 100could be implemented using the signal generating device 10 describedabove in reference to FIGS. 1 to 3, or using any other suitableimplementation.

The method 100 starts at 105. At step 110, the method 100 optionallyprovides for the generation of a first input pulse signal having aninput pulse duration. This can be done using a typical pulse generator.The input pulse signal defines an attack portion, a decay portion and asustain portion extending therebetween. The input pulse signal is thenfed to the input port of one of a duplicator (optionally via acompressor) for step 120 to follow.

Then, at step 115, the method optionally includes compressing in time atleast one of the attack portion and the decay portion of the first pulse(also referred to as pulse edges) to produce a fast edges first pulse.

Then, at step 120, the method includes duplicating the fast edge firstpulse provided at step 115, or the input pulse signal directly wherestep 115 is omitted, to produce a first and a second digital pulsesignal. The duplicating can be performed by first converting the inputpulse signal into a digital pulse signal using an analog-to-digitalconverter for example, and then duplicating the digital pulse signal toobtain the first digital pulse signal and the second digital pulsesignal.

Afterwards, at step 125, at least one of the first and second digitalpulse signals are delayed in time by a time delay to obtain respectivelya first and a second delayed digital pulse signal having a time delaydifference based on the output pulse duration. The time delay differenceto be obtained between both delayed signals is generally chosen as beingsubstantially equal to the output pulse duration desired. Where bothfirst and second digital pulse signals are each delayed respectively bya first time delay and a second time delay, each time delay may beadjusted or implemented accordingly.

Finally, at step 130, the first and the second delayed digital pulsesignals are logically combined to generate an output pulse signal withan output pulse duration smaller than the input pulse duration. Step 130involves, for example, using a logic circuit which implements a truthtable as that provided in TABLE 1.

As detailed herein above, the logic combination of step 130 is in thedigital realm, and thus independent of a voltage level value associatedwith the input pulse signal.

The method ends at step 135, where the output pulse signal is outputtedor, for example, released at an output port to drive an electronic orelectrical circuit such as as an amplifier, an amplifier driver, amodulator, an electro-optical circuit, a laser, a pulsed laser, a radar,a LIDAR, etc.

In the above-described method 100, at least one of the first and seconddigital pulse signals produced at step 120 can be inverted, using forexample a logical inverter, either within the logic circuit 42, oroutside of the logic circuit 42. In other words, the method 100 may havean additional step of inverting, for example, one of: the input pulsesignal after step 110, during step 115 or after step 115; the first andthe second digital pulse signals at or after step 120; and the first andthe second delayed digital pulse signals after step 125, before or atstep 130.

An additional step may also be provided to produce a balanced signal sothat all the pulses downstream from the additional balanced signalproduction step are differential signals, and all pulses presentupstream of the balanced signal generation step are single-endedsignals.

FIG. 5 illustrates an example of an output pulse signal 200 versus timeand a series of pulses 202 each having an output pulse duration 204 inaccordance with an embodiment.

The above described pulse generating device and method may beimplemented using differential logic components. Differential logic isgenerally interesting for decreasing the noise sensitivity and theElectromagnetic Interference (EMI) emission levels.

Contrary to the use of traditional NOT gates which typically increasetransition time and tend to be prone to environmental conditions, theuse of differential signals can also permit quicker inversion of signalssince in such a case, an inversion can be achieved simply by reversingthe polarity of the signal. Such an inversion can be done before orafter the delay component 38 (or 40) or the delaying at step 125, amongother possibilities.

In addition, the above described pulse generating device and method maybe adapted for use with relatively low quality input pulse signalspresenting for example high noise levels and/or relatively slow varyingslopes. This is done by having a high gain, saturable amplifier, or anadditional step of amplifying the input pulse signal or reducing a noiselevel, in or before the signal duplicator 23 (or the duplicating step120). Such amplification minimizes the influence of noise on the shapeand timing of the output pulse signal by taking advantage of inputhysteresis for example.

Although the present pulse generating method and device have beendescribed hereinabove by way of exemplary embodiments thereof.Modifications which can be made without departing from the scope of thesubject matter as defined in the appended claims are considered asforming part of the present specification.

1. A pulse generating device for generating an output pulse signalhaving an output pulse duration, the device comprising: a signalduplicator for receiving an input pulse signal comprising an input pulseduration, the signal duplicator for duplicating the input pulse signalinto a first digital pulse signal and a second digital pulse signal eachcomprising the input pulse duration; a delay component operativelycoupled to the signal duplicator, the delay component for delaying atleast one of the first and the second digital pulse signals by a timedelay to obtain respectively a first and a second delayed digital pulsesignal, a time delay difference between the first and the second delayeddigital pulse signals being substantially equal to the output pulseduration; and a logic circuit coupled to the delay component, the logiccircuit for combining logically the first and the second delayed digitalpulse signals to generate the output pulse signal with the output pulseduration smaller than the input pulse duration, the logic circuit foroutputting the output pulse signal.
 2. The pulse generating device ofclaim 1, wherein the logic circuit is for generating the output pulsesignal independently of a voltage value associated with the input pulsesignal.
 3. The pulse generating device of claim 1, comprising acompressor for compressing at least one of pulse edges of the inputpulse signal in time, prior to the duplicating.
 4. The pulse generatingdevice of claim 1, wherein the signal duplicator comprises ananalog-to-digital converter to convert the input pulse signal into adigital pulse signal, prior to duplicating the digital pulse signal intothe first digital pulse signal and the second digital pulse signal. 5.The pulse generating device of claim 1, comprising a pulse generatorcoupled to the signal duplicator for generating the input pulse signalcomprising the input pulse duration, the pulse generator being coupledto the signal duplicator via an input port.
 6. The pulse generatingdevice of claim 1, wherein the logic circuit comprises at least one ofan XOR gate, a NOR gate, an XRN gate and an AND gate.
 7. The pulsegenerating device of claim 1, wherein the signal duplicator, the delaycomponent and the logic circuit are integrated within a single circuitdevice.
 8. The pulse generating device of claim 1, wherein the delaycomponent comprises an adjustable delay component.
 9. The pulsegenerating device of claim 1, wherein the delay component comprises atleast two delay components each for respectively delaying the first andthe second digital pulse signals by a first and a second time delayrespectively, the time delay difference corresponding to a differencebetween the first and the second time delays.
 10. The pulse generatingdevice of claim 1, comprising a logical inverter coupled between one of:the signal duplicator and the delay component, and the delay componentand the logic circuit, for inverting one of: the first and the seconddigital pulse signals; and the first and the second delayed digitalpulse signals.
 11. The pulse generating device of claim 1, comprising aphase splitting device coupled to the signal duplicator, the phasesplitting device producing complementary input pulse signals and feedingthe complementary input pulse signals to the signal duplicator.
 12. Thepulse generating device of claim 1, wherein the logic circuit comprisesa differential logic component for inverting the first delayed digitalpulse signal and the second delayed digital pulse signal.
 13. A methodfor generating an output pulse signal having an output pulse duration,the method comprising: receiving at an input port of an electronicdevice an input pulse signal comprising an input pulse duration;duplicating the input pulse signal into a first digital pulse signal anda second digital pulse signal each comprising the input pulse duration;delaying at least one of the first and the second digital pulse signalsby a time delay to obtain respectively a first and a second delayeddigital pulse signal, a time delay difference between the first and thesecond delayed digital pulse signals being substantially equal to theoutput pulse duration; logically combining the first and the seconddelayed digital pulse signals to generate the output pulse signal withthe output pulse duration smaller than the input pulse duration; andoutputting the output pulse signal at an output port of the electronicdevice to drive an electronic or electrical circuit.
 14. The method ofclaim 13, wherein the logically combining is performed independently ofa voltage value associated with the input pulse signal.
 15. The methodof claim 13, wherein the duplicating comprises converting the inputpulse signal into a digital pulse signal, the first digital pulse signaland the second digital pulse signal being duplicated from the digitalpulse signal.
 16. The method of claim 13, wherein the duplicatingcomprises reducing a noise level in the input pulse signal.
 17. Themethod of claim 13, comprising generating the input pulse signalcomprising the input pulse duration, and sending the input pulse signalto the input port.
 18. The method of claim 13, comprising compressing atleast one of an attack portion and a decay portion of the input pulsesignal in time, prior to the duplicating, the attack portion and thedecay portion defining pulse edges about a sustain portion of the inputpulse signal.
 19. The method of claim 13, wherein at least one of thelogically combining and the outputting comprises logically switching agate to output the output pulse signal with an output pulse ratecorresponding to one of: an input frequency of the input pulse signaland twice the input frequency.
 20. The method of claim 13, comprisinginverting one of: the input pulse signal, the first and the seconddigital pulse signals; and the first and the second delayed digitalpulse signals.